Litcius/Paper detail

Compact Filtering Patch Antenna Arrays for Marine Communications

Liu Gui, Yongmei Pan, Xiu Yin Zhang

2020IEEE Transactions on Vehicular Technology62 citationsDOI

Abstract

A planar 2 × 2 filtering patch antenna array with high selectivity and wide stopband is investigated for marine communications. The 2 × 2 patch array is composed of a driven patch and four identical parasitic patches placed nearby. A forked-microstrip-line-coupled rectangular slot is used to excite the driven patch, while the neighboring parasitic patches are capacitively coupled by the driven patch. Owing to the hybrid feeding effect of the forked feed line, a radiation null can be generated at the lower band-edge. Simultaneously, another radiation null can be generated at the upper band-edge owing to the radiation cancellation effect between the driven patch and the parasitic patches. Consequently, no power dividing feeding network is required for the 2 × 2 array, and the quasi-elliptic bandpass filtering response is achieved without utilizing any complex filtering/non-filtering circuits. In addition, the proposed filtering array exhibits a wide stopband capable of suppressing the second-harmonic radiation effectively. Based on this 2 × 2 array, a larger 4 × 4 filtering array is further designed by just using a traditional four-way power dividing network. For validation, both of the 2 × 2 and 4 × 4 filtering patch arrays operating at 5.25 GHz are fabricated and tested. The measured results show that the two patch arrays have comparable impedance bandwidths of about 4.4%. The in-band peak gains are given by 11.1 and 15.5 dBi respectively, which are suitable for the long-distance shore-to-ship communications.

Topics & Concepts

StopbandPatch antennaMicrostripPlanar arrayAntenna (radio)Microstrip antennaAntenna arrayAcousticsElectronic circuitNull (SQL)Electronic engineeringPhysicsBand-pass filterEngineeringComputer scienceOpticsElectrical engineeringDatabaseAntenna Design and AnalysisMicrowave Engineering and WaveguidesMillimeter-Wave Propagation and Modeling